JP2021506220A - DC-DC converters, bidirectional charging systems, and automobiles - Google Patents

Abstract

The present invention relates to a DC-DC converter (1) for a charger of a battery (26) of an electric accumulator connected to a power network, capable of bidirectional operation and at least one resonant full bridge. Each resonant full-bridge LLC converter, including an LLC converter (20), is a rectifier (24) that rectifies a signal amplified by a transformer (23), a transistor (301), a diode (302), and a capacitor (303). ) Includes a rectifier (24) formed by a full bridge of four parallel structures (240, 240', 240'', 240''') mounted in parallel. Each parallel structure (240, 240', 240'', 240''') of the rectifier (24) is associated with the parallel structure (240, 240') when the DC-DC converter (1) operates in indirect mode. It is characterized by including a device (40) for canceling the effect of the capacitor (303) of', 240'', 240'''). [Selection diagram] Fig. 2

Description

The present invention relates to a DC-DC converter for a bidirectional charger that charges the battery of an electric accumulator.

Traditional chargers for charging the battery of an electric accumulator are unidirectional, which only allows the electric accumulator to be recharged from an external power grid, which is generally in the charging direction or in order. It is called the direction.

Such a unidirectional charger for charging the battery of an electric accumulator is commonly known as a power factor improvement stage, also known as the abbreviation PFC, and a chopper, more commonly DC-DC. It is composed of a DC-DC conversion stage called a stage.

However, recently, it is also useful to enable the electric power stored in the accumulator capacitor to be supplied to an external power grid, and a bidirectional charger has been referred to. The supply of current by the battery of the electric accumulator to the external power grid is said to be in the discharge direction or in the opposite direction.

One known challenge is to adapt the conventionally known unidirectional accumulator chargers to bidirectional chargers.

In particular, unidirectional chargers known from the prior art for applications requiring high power densities implement a full bridge LLC resonant DC-DC converter, as shown in FIG. 1 of the prior art.

Such a converter 10 makes it possible to achieve good efficiency, low EMC traces and low bulk. It also allows so-called "soft" switching to be implemented, reducing switching losses commonly occurring during conventional pulse width modulation operations.

The full bridge LLC resonant converter 10 according to FIG. 1 includes a full switching bridge 11 that produces a square wave signal or current that excites an LLC circuit 12 formed by a capacitor and two inductors. Then, the LLC circuit 12 generates a resonant sinusoidal current in the transformer 13. This resonant sinusoidal current is rectified by the rectifying bridge 14. The rectified signal / current is then filtered by the output capacitor 15 before being collected by the battery 16.

The assembly formed by the full switching bridge 11 and the LLC circuit 12 is referred to as the primary circuit or primary portion of the converter, and the assembly formed by the rectifying bridge 14 and the output capacitor 15 is the secondary circuit or secondary of the converter. It is said to be a part. In other words, in the forward operation of the charger, the current is sent from the primary side to the secondary side and the forward operation of the converter is referenced.

Soft switching is realized by a zero voltage switching (ZVS) type on the primary side and a zero current switching (ZCS) type on the secondary side. This constitutes a solution that allows the use of higher switching frequencies.

However, in order to realize a bidirectional charger, a relatively efficient, robust and inexpensive DC-DC converter is required.

Proposed is a DC-DC converter of a charger for charging the battery of an electric accumulator connected to the power grid, charging the battery in the forward direction and discharging the battery to the power grid in the reverse direction. By being able to operate in both directions, including at least one full bridge LLC resonance converter,
Each full bridge LLC resonant converter
-A full switching bridge that produces a square wave signal, including a full bridge assembly with four structures each formed by transistors, diodes, and capacitors connected in parallel.
-An LLC circuit containing a capacitor and two inductors and excited by a square wave signal,
-A transformer that transmits signals from an LLC circuit,
-A rectifier that rectifies a signal transmitted by a transformer, a rectifier formed by a full bridge having four structures formed by transistors, diodes, and capacitors connected in parallel.
-A DC-DC converter that includes an output capacitor that filters the rectified signal.

Each structure of the rectifier further includes a device for removing the influence of the capacitor of the related structure when the DC-DC converter operates in the forward mode. As a result, a reversible DC-DC converter can be realized, the charger can be operated in both directions, and a highly efficient and relatively reliable charger can be realized.

The removal device (ledit dispositif d'annulation), not limited to its advantage,
-Another transistor connected in series with the capacitor of the relevant structure between the capacitor of the relevant structure and the anode of the diode of the relevant structure,
-An RC assembly that includes a resistor and another capacitor in parallel, with the RC assembly connected between the gate of the other transistor and the anode of the diode of the associated structure.
-Contains a diode connected by the cathode to the gate of the other transistor and by the anode to the gate of the transistor of the relevant structure.
As a result, the removal device can be obtained at a relatively low cost.

The converter includes, without limitation, two full-bridge LLC resonant converters in parallel. As a result, the efficiency and reliability of the device can be improved.

The present invention is a bidirectional charging system for charging the battery of the electric accumulator, which includes a power grid, a power factor improving rectifier stage, the above-mentioned DC-DC converter, and a battery of the electric accumulator. Regarding the charging system.

The present invention also relates to an automobile provided with the bidirectional charging system according to the present invention.

Other specific features and advantages of the invention will become apparent by reading the description given below for one particular embodiment of the invention, provided by way of illustration, but not limitation, with reference to the accompanying drawings. Will.

FIG. 1 is a diagram of a DC-DC converter known from the prior art. FIG. 2 is a diagram of a DC-DC converter according to the first embodiment of the present invention. FIG. 3 is a diagram of a DC-DC converter according to a second embodiment of the present invention. FIG. 4 is a detailed view of the structure of the rectifier of the converter according to the first embodiment or the second embodiment of the present invention.

Referring to FIG. 2, in the first embodiment of the present invention, the charger (not shown in its entirety) is a DC-DC converter including a power factor improving rectification stage called PFC and a bidirectional full bridge LLC resonance converter 20. Includes 1.

The full bridge LLC resonant converter 20 includes a full switching bridge 21 that produces a square wave signal or current that excites an LLC circuit 22 consisting of a capacitor and two inductors. Then, the LLC circuit 22 generates a resonant sinusoidal current that is transmitted by the transformer 23 and rectified by the rectifying bridge 24. The rectified and amplified signal / current is then filtered by the output capacitor 25 before being collected by the battery 26.

The assembly formed by the full switching bridge 21 and the LLC circuit 22 is called the primary circuit or primary part of the converter, and the assembly formed by the rectifier 24 and the output capacitor 25 is the secondary circuit or secondary part of the converter. Is called.

In the bidirectional operation of the charger, when current is sent from the primary side to the secondary side of the converter 20, it refers to the forward direction of operation of the converter 20 and thereby the battery from the external power grid connected to the primary side. 26 can be recharged. The charger is further designed to operate in the opposite direction in which the energy stored by the battery 26 is transmitted from the secondary side to the primary side of the converter 20 so as to supply it to the external power grid.

Switching bridge 21 includes four switching arms, each structure 210, 210 ^{', 210'} 'are formed by 210'^''. The structure includes electronic components connected in parallel with each other.

Each structure 210, 210 ^′ , 210 ^″ , 210 ^″ includes a diode, a transistor, and a capacitor.

Structures 210, 210 ^′ , 210 ^″ , 210 ^″ are well known to those skilled in the art and are connected as full bridges.

The LLC circuit 22 and the transformer 23 are the same as those of the prior art described above.

The rectifier 24 of the secondary circuit includes a full bridge formed by four switching arms.

Each switching arm is formed by structures 240, 240 ^′ , 240 ^″ , 240 ^″ , and the structure includes electronic components connected in parallel with each other.

Referring to FIG. 4, each structure 240, 240 ^′ , 240 ^″ , 240 ^{′ ″} includes a diode 302, a transistor 301, and a capacitor 303 in a full bridge rectifier connection.

The capacitor 303 of the secondary circuit makes it possible to slow down the voltage rise, and can cut off the current without loss and in a state of a small overvoltage.

Specifically, since the structure of the converter 20 is not symmetrical, the chopped current on the secondary side becomes higher than the chopped current on the primary side when the converter operates in the opposite direction (discharge direction).

The capacitor 303 on the secondary side has an effect of adversely affecting the efficiency of the DC-DC converter 20 during the forward operation of the DC-DC converter 20.

To correct this shortcoming, each structure 240, 240 ^' , 240 ^'' , 240 ^''' of the rectifier 24 further includes a blocking assembly 40 (montage de coupure 40), whereby the forward direction of the converter 20. during the operation, the structure of the rectifier 24 240, 240 ^{', 240'} ', (also called snubber) capacitor 240'^'' 303 it is possible to eliminate the influence on the secondary side.

Referring to FIG. 4, the structure 240, 240 ^{', 240'} ', 240'^'' this blocking assembly 40 associated with the relevant structures 240, 240 ^{', 240'} ', 240' and capacitor ^'' structure 240, 240 ^{', 240'} ', 240'^'' between the anode of the diode of the structure 240, 240 ^{', 240'} ', 240'^'' to be connected in series, associated structures 240, 240 ^', In contrast to the 240 ^'' , 240 ^''' transistors 301, it includes the other transistor 401 or the transistor 401 called the breaking transistor 401.

Blocking assembly 40 also a resistor 404 and another capacitor 403 comprises an RC assembly 405 including the parallel, RC assembly 405, the structure 240, 240 associated with the gate of the other transistor 401 ^{', 240'} ', 240 It is connected to the anode of the ^''' diode 302.

Blocking assembly 40 also cathode by being connected to a gate of the other transistor 401, the structure 240, 240 associated with the anode ^{', 240'} 'includes a diode 406 connected to the gate of the transistor 301 of 240'^'' ..

The transistor 401 used to cut off the current has a very low specification as compared with the transistor 301 having a structure. For example, the breaking transistor 401 has an impedance of 10 ohms, whereas the transistor 301 of the structure has 100,000 ohms, or 10,000 times the impedance.

In this way, commands for activating the shutoff and shutoff assembly 40 are automatically generated.

It has the advantage of increasing the efficiency of the bidirectional converter and reducing overvoltage at a relatively low cost.

Referring to FIG. 3, according to the second embodiment of the present invention, the bidirectional charger, DC-DC conversion stage 1 comprising two DC-DC converters 20, 20 ^'as described in the first embodiment including the ^'. Two DC-DC converter 20, 20 ^'are connected in parallel and controlled by the micro electronic card 500.

Structure to place the DC-DC converter 20, 20 ^'in parallel, relatively high in robustness, allowing to withstand a large current.

It should be noted that the present invention is not limited to only two DC-DC converters connected in parallel, and may include more converters connected in parallel.

According to the present invention, the charger can be operated in both directions, and a highly efficient and relatively reliable charger can be realized.

Claims (5)

A DC-DC converter (1, 1 ^' ) of a charger for charging the battery (26) of an electric accumulator connected to the power grid, charging the battery (26) in the forward direction and in the reverse direction. It is capable of bidirectional operation by discharging the battery (26) into the power grid and includes at least one full bridge LLC resonance converter (20).
Each full bridge LLC resonant converter (20)
A full switching bridge (21) for generating a square wave signal, parallel-connected transistors (301, 401), diodes, and four structure formed respectively by capacitor (210, 210 ^{', 210'} ', A full switching bridge (21), including a full bridge assembly with 210 ^'''' ), and
An LLC circuit (22) that includes a capacitor and two inductors and is excited by the square wave signal.
A transformer (23) for transmitting the signal from the LLC circuit (22) and
A rectifier (24) that rectifies the signal transmitted by the transformer (23), and has four structures (reach) formed by transistors (301), diodes (302), and capacitors (303) connected in parallel. With a rectifier (24) formed by a full bridge assembly with 240, 240 ^' , 240 ^'' , 240 ^''' ),
Includes an output capacitor (25) that filters the rectified signal.
Each structure of the rectifier (24) (240, 240 ^{', 240'} ', 240'^''), when the DC-DC converter (1) is operated in the forward mode, related structures (240, 240 ^' , 240 ^'' , 240 ^'''' ) DC-DC converter, further comprising a device (40) for removing the influence of the capacitor (303). The DC-DC converter (1, 1 ^' ) according to claim 1.
The removal device (40)
The associated structures (240, 240 ^{', 240'} ', 240'^'') the capacitor (303) and the associated structures (240, 240 ^{', 240'} ', 240'^'') wherein the diode (302 ) With another transistor (401) connected in series with the capacitor (303) of the relevant structure (240, 240 ^' , 240 ^'' , 240 ^''' ).
A resistor (404) and another capacitor (403) and an RC assembly comprising in parallel (405), the gate and the associated structure of the other transistor (401) (240, 240 ^{', 240'} ', ^240''' ) The RC assembly (405) connected between the diode (302) and the anode,
Wherein the cathode is connected to the gate of the other transistor (401), the related structure by the anode (240, 240 ^{', 240'} ', 240'^'') connected to the gate of the transistor (301) Diodes ( A DC-DC converter including 406). The DC-DC converter (1 ^' ) according to claim 1 or 2.
A DC-DC converter including two full-bridge LLC resonant converters (20, 20 ^' ) in parallel. A two-way charging system for charging the battery (26) of an electric accumulator.
A bidirectional charging system including a power grid, a power factor improving rectification stage, a DC-DC converter (1, 1 ^' ) according to any one of claims 1 to 3, and a battery (26) of an electric accumulator. An automobile comprising the bidirectional charging system according to claim 4.